1. No category

"Clone": The History of a Euphonious Scientific Term

Medical History, 2002, 46: 381-402
"Clone": The History of a Euphonious
Scientific Term
URSULA MITTWOCH*
"When I use a word", Humpty Dumpty said
.
.
.
"it means just what I choose it to mean."'
It is rare for a scientific term to be adopted by the public, but this has clearly
happened to the word clone and its derivative, cloning; and public reaction, dominated
by apprehension that cloning might be applied for the production of human babies,
has been consistently negative.2 To establish the scientific basis from which public
opinion stems is not easy. Indeed, the question: "What is a clone?", has no unequivocal
answer. In a recent article in Science, Anne McLaren wrote that "Over the years,
clones and cloning have meant different things to different people",3 surely an
unsatisfactory state of affairs for a scientific term.
The present article will follow the development of the different uses of the word
clone from when it was first coined close to a century ago to the present. I shall
argue that the popular identification of a clone with an organism that is akin to a
carbon copy of the original is a relic from an earlier stage of the evolution of the
term. Indeed, the same point was made by Lee M Silver in a recent Nature essay.4
It would seem that, following the acceptance of Mendelian inheritance at the
beginning of the twentieth century, it became widely assumed that organisms are
totally specified by the nuclear genotype. This resulted in both scientists and the
media ignoring other developmental differences to which organisms are subjected,
either for the sake of simplifying the message or with a view to increasing its impact
on the public.
* Professor Ursula Mittwoch, Department of
Biology, Galton Laboratory, University College
London, 4 Stephenson Way, London NW1 2 HE,
UK. [email protected]
transcribing them; also Dr Ann Burgess for
helpful comments, and Dr Jon Turney and two
anonymous referees for constructive criticism of
an earlier version of the manuscript.
I am greatly indebted to the Librarians of the
British Library, of University College London,
The Wellcome Library, The Royal Society of
Medicine and the Linnean Society for their help
with locating references. I wish to thank Dr
Derek Chadwick, Director of the Novartis
Foundation, and Ms Jane Dempster, for making
available the original tape recordings of the Ciba
Foundation Symposium on 'Man and his future',
referred to in notes 73 and 84, and to Professor
Stuart Rosen and Mrs Mary Wykes (UCL
Phonetics and Linguistic Department) for
'Lewis Carroll, Through the looking glass, and
what Alice found there, Basingstoke, Macmillan
Children's Books, reprinted 1997 from text of
1897, p. 113.
2
Wellcome Trust, Public perspectives on
human cloning: a social research study, London,
Wellcome Trust, 1998, p. 4.
3Anne McLaren, 'Cloning: pathways to a
pluripotent future', Science, 2000, 288: 1775-80.
4Lee M Silver, 'What are clones?', Nature,
2001, 412: 21.
381
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Ursula Mittwoch
Vegetative Reproduction: The Search for a Scientific Term
The story begins at the turn of the twentieth century, when Herbert J Webber was
in charge of the Plant-Breeding Laboratory of the United States Department of
Agriculture. In 1899, Webber had travelled to London in order to attend a conference
on hybridization, organized by the Royal Horticultural Society, and reported that
work on hybridization as a means of securing variation and improvements had only
recently begun, chiefly on oranges, pineapples, apples, pears, wheat, corn and cotton.5
The year 1900 witnessed the rediscovery of Mendel's paper by three European
botanists,6 and in the following year an English translation ofthe paper was published,
with a foreword by William Bateson.7
While the new science provided increased opportunities for plant breeders, the
majority of gardeners and fruit producers seek uniformity rather than variation in
their produce, and throughout history they endeavoured to by-pass the participation
of ovules and pollen in the propagation of many food plants. Following the
dissemination of Mendel's laws, Webber was searching for a scientific term to denote
those plants that are propagated vegetatively by buds, grafts, cuttings, suckers,
runners, slips, bulbs, tubers, etc. Such plants, he wrote, "are not individuals in the
ordinary sense, but are simply transplanted parts of the same individual, and in
heredity and in all biological and physiological senses such plants are the same
individual".8
Webber emphasized that he was looking for a term that could be used and
understood by the general public. It should, therefore, be short, euphonious, phonetically spelled, easily pronounced and different from any other word in ordinary
use, so that it would not suggest any meaning other than the one desired. He
suggested the word clon, from the Greek KAOV, meaning a twig, spray or slip, such
as is broken off for propagation. Clon (plural clons, adjective clona!) was to be
applied to varieties of apples, pears, strawberries, etc., that are not propagated from
seeds, to distinguish them from plants such as wheat and corn that are grown from
seed. The word was to be pronounced with a long o, as in Greek.
Subsequently, Charles Louis Pollard, of Springfield, Massachusetts, suggested an
improvement in orthography.9 He pointed out that one of the definite indications of
quantity in English words was in the final e, as in tone, bite, hate etc.; and even
though recent American usage had sometimes dispensed with the final e, it seemed
important to distinguish the derivation from the Greek word KAcov from that of
KAovos (the latter having given rise to the English adjective clonic). If written clon,
the word would naturally be pronounced clon. ' He suggested that clone be adopted
as the correct form. The new spelling became widely accepted.
'Herbert J Webber, 'Work of the United
States Department of Agriculture on plant
hybridisation', J. r. hort. Soc., 1900, 24: 128-45,
pp. 128, 131-4, 138.
6Robert Olby, Origins of Mendelism, 2nd ed.,
Chicago University Press, 1985, pp. 109-37.
7Gregor Mendel, 'Experiments in plant
hybridisation. With an introductory note by W.
Bateson', J. r. hort. Soc., 1901, 26: 1-32.
8Herbert J Webber, 'New horticultural
and agricultural terms', Science, 1903, 18:
501-3.
'Charles Louis Pollard, 'On the spelling of
"clon"', Science, 1905, 22: 87-8.
'°Idem, "'Clon" versus "Clone"', Science,
1905, 22: 469.
382
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"Clone"
Classical Definitions
The term clone was defined by Crane and Lawrence as "the collective name of all
the plants asexually reproduced by division, grafting, etc., from one (seedling)
individual"." The authors pointed out that this method of reproduction had had a
prominent place in horticulture for centuries, and was often the only means of
perpetuating important varieties. C D Darlington defined clone as "a group of
organisms descended by mitosis from a common ancestor".'2 While this definition
would include animals, the examples he discussed were confined to plants bearing
an extra chromosome (trisomics), or which are heterozygous for chromosomal
changes. Many such plants are sterile, and if they do set viable seed, they fail to
breed true.
The definitions given above emphasize that originally clone was a collective noun,
referring to a group, all ofwhose members were descended by vegetative reproduction
from a common, sexually produced, ancestor. A B Stout introduced the term ramet
to denote the independent members of a clone.'3 He added that "[t]he botanical
status of the entire group of plants (ramets) constituting a clon is precisely that of
the individual plant ... from which the clon was derived". W B Turrill wrote that
"with many perennial species hundreds of ramets (the physiologically independent
'individuals' of a clone) can be produced within a year".'4 He further stated that
these ramets were all of the same genetic constitution, apart from rare somatic
mutations, so that a high degree of uniformity could be achieved. The word ramet
is included in the Oxford English Dictionary.'"
It is evident that vegetative propagation plays an important role in ensuring the
production of uniform crops of many plants of economic importance, and this fact,
coupled with the ease with which the word clone is pronounced and remembered,
caused the term to enter into the vocabulary of a wider public. In 1928, The Times
printed a Reuters' report stating that the Rubber Research Institute of the Federated
Malay States had issued a communique, which included the statement that, in a
tapping of buddings carried out by the Institute, the highest-yielding clone had latex
vessels of much smaller bore than the lowest-yielding clone. This was followed by
an explanation in parentheses: "(Note - Clone is the term given to all bud grafts
taken from a particular parent tree)".'6 Some years later, the Economist selected the
following item from a chairman's report: "we also have an interest in Namoe Tongan
Rubber Estates in Sumatra, which have been planted with selected high yielding
clones".'7
" M B Crane and W J C Lawrence, The
genetics of garden plants, London, Macmillan,
1934, p. 213.
2 C D Darlington, Recent advances in cytology,
2nd ed., London, Churchill, 1937, p. 574.
3 A B Stout, 'The clon in plant life', J. New
York bot. Garden, 1929, 30: 25-37, p. 33.
" W B Turrill, British plant life, London,
Collins, 1948, p. 128.
'5 The Oxford English Dictionary, 2nd ed.,
Oxford, Clarendon Press, 1989.
"6Reuters' Report, 'Potential rubber tree
yields', The Times, 20 July 1928, p. 20.
" 'Langen (Java) Rubber Estates
Company-Improved results-strong position',
Economist, 26 Jan. 1935, 120: 212.
383
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Ursula Mittwoch
However, neither economic success nor popular interest in fruits such as apples,
strawberries and bananas inspired the mass media to take an interest in clones. This
happened only after the word was applied to organisms that were very different
from the crop plants of agriculture and horticulture, and the development of new
techniques of culturing them. I shall briefly review the steps that led to consecutive
changes in the meaning of the term.
Life Cycles of Protozoa: Clones and Pure Lines
During the course of the nineteenth century, techniques were developed that
allowed protozoa to be cultured and accurately observed under the microscope. In
1888, E Maupas published a detailed description of the methodology for culturing
ciliate protozoa, including three species of Paramecium, specifying glassware, and
the different food organisms that needed to be present in the drops of water containing
the different species of protozoa, both carnivores and vegetarians. Each isolated
individual had to be followed on a daily basis, and the same applied to each of its
offspring and future generations.
It emerged that these animals could multiply by binary fission for varying numbers
of generations, but that eventually the line would die out unless sexual reproduction,
in the form of fusion between two individuals, took place.'8A subsequent investigation
by H S Jennings on variation and inheritance in protozoa, published in 1929, dealt
with the question of the extent to which variation can occur between individuals
within a line of asexually produced offspring, and contained a subheading 'The
occurrence and inheritance of variation within clones, with the results of selection'.'9
The word clone was defined as follows: "All the individuals descended by uniparental
reproduction from a single individual constitute a clone. A single clone has at times
been called a 'pure line.' A series of successive generations descended under culture
from some member of a clone is commonly spoken of as a line; sometimes as a
series."20 Selection experiments were undertaken in order to discover whether diverse
biotypes, i.e. hereditary constitutions, could be isolated from a single clone.
The concept of the pure line, offered as a synonym for clone, was originally
introduced by W Johannsen2' to describe all individuals originating from a single
self-fertilizing individual: "Mit einer reinen Linie bezeichne ich Individuen, welche
von einem einzelnen selbst-befruchtenden Individuum abstammen" ("by pure line I
designate individuals that are descended from a single self-fertilizing individual"). The
term "selbst-befruchtenden", i.e. "self-fertilizing", demonstrates that in Johannsen's
terminology, the concept of the pure line was applied to a sexually reproducing
organism, such as the garden bean, Phaseolus vulgaris, and not to vegetative
reproduction.
18 E Maupas, 'Recherches experimentales sur
Ia multiplication des infusoires cilies', Arch. Zool.
exp. gen., 1888, 6: 165-277, pp. 191, 179-84,
254-9.
'9 H S Jennings, 'Genetics of the protozoa',
Bibl. Genet., 1929, 5: 105-330, p. 232.
20Ibid., p. 126.
21 WJohannsen, Ueber Erblichkeit in
Populationen und in reinen Linien. Ein Beitrag zur
Beleuchtung schwebender Selektionsfragen, Jena,
Fischer, 1903, p. 9.
384
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"Clone"
The admixture of the concepts of clone and pure line was accepted by Robert
Harrington in 1975, when he applied the term clone to an hermaphrodite species of
fish that reproduces by self-fertilization. He wrote that "Selfing in the wild had
already reduced the fish within each of the three lines of our stock to genetic
uniformity, viz. isogenicity plus homozygosity. These lines are referred to as homozygous clones. This usage of the term 'clone' avoids repeated circumlocution and
means a group or line of descent composed of uniparental, isogenic individuals".22
The term clone has also been applied to all-female species of lizards belonging to
the genus, Cnemidophorus, which reproduce by diploid parthenogenesis and are
genetically homogeneous, although many species are heterozygous.23
Jennings' 1929 paper had been preceded by an earlier one published in 1916, in
which he challenged Johannsen's claim that selection within pure lines was ineffective.
According to Jennings, selection of characteristics such as number and length of
spines on the shell of the protozoan, Difflugia corona, was effective even within the
progeny of a single individual. He did not, however, use the word clone, but family,
for all the individuals descended by fission from one original parent.24
Cultures of Cells from Multicellular Organisms
In addition to the study of protozoa, the second half of the nineteenth century
also witnessed the development of the scientific study of bacteriology.25
discovered the nature of fermentation, Louis Pasteur devised special liquid media
for their culture, while Robert Koch developed solid media for the isolation of pure
cultures.
In the early twentieth century, pathologists adapted the techniques for culturing
micro-organisms for the study of human cells and those of other multicellular
organisms.26 As in bacteria, techniques were worked out to enable quantitative
studies to be made of the rate of growth of normal and cancer cells in vitro. However,
the problem of obtaining pure cultures from an original inoculum containing many
cells proved to be harder than in micro-organisms.27
for several decades was that cultures failed to grow unless the original inoculum
consisted of a large number of cells. The problem was solved for the first time in
1948 by Katherine Sanford and collaborators at the USA National Cancer Institute.28
Having
A
22 R W Harrington, 'Sex determination
differentiation among uniparental homozygotes of
the hermaphroditic fish, Rivulus marmoratus
(Cyprinodontidae: Atheriniformes)', in R
Reinboth (ed.), Intersexuality in the animal
kingdom, Berlin and New York, Springer, 1975,
p. 249.
23
J Cole, 'Unisexual lizards', Sci. Am.,
Jan. 1984, 250: 84-90, 118, p. 85.
2
S Jennings, 'Heredity, variation and the
results of selection in the uniparental
reproduction ofDifflugia corona', Genetics, 1916,
1: 407-534, pp. 419, 532-3.
2S W W C Topley and G S Wilson, The
principles of bacteriology and immunity, 2 vols,
and
Charles
London,
major
Edward
difficulty
that
persisted
Arnold, 1929, vol. 1,
pp.
1-14,
212-23.
26 Fischer, Tissue culture: studies in
experimental morphology and general physiology
of tissue cells in vitro, London, William
Heinemann (Medical Books), 1925, pp. 19-34.
27
Henry Harris, The cells of the body: a
history of somatic cell genetics, Cold Spring
Harbor Laboratory Press, 1995, pp. 31-56.
28Katherine K Sanford, Wilton R Earle and
Gwendolyn D Likely, 'The growth in vitro of
single isolated tissue cells', J. natl. Cancer Inst.,
1948, 9: 229-46.
385
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Ursula Mittwoch
Their publication carried the following introduction: "One obstacle to the more
accurate use of tissue culture, particularly in cancer research, has been the inability
to grow a single, isolated, cell into a clone or pure culture."29
The reason for previous failures turned out to be the inadequacy of even the best
culture media, which needed extensive modification by large numbers of cells before
they could be utilized. Accordingly, the authors reduced the volume of medium
surrounding individual cells by growing them in capillary tubes, and also used
conditioned medium, in which cells had been grown previously.30 The new technique
resulted in the establishment of a clone culture of strain L sarcoma-producing cells
from mice of the C3H strain.3' Such cultures did not, however, always retain their
homogeneity. Some years later, the authors reported that two sub-lines derived from
a clone cell culture that had originated from a single cell differed in morphology as
well as in their ability to induce sarcomas when injected into mice.32
Theodore Puck and Philip Marcus devised a simplified technique for producing
cultures of HeLa (human cervical carcinoma) cultures from single cells. Instead of
limiting the amount of medium available to individual cells, they plated them out
onto a confluent layer of cells that had been killed by irradiation.33 In a subsequent
publication, Puck and his colleagues gave the following definition of clone: "A clone
is a population, all of whose members are descendants from the same single
organism".34 But can a single mammalian cell be regarded as an organism? And
could this definition not be equally applied to any cell culture derived from an
individual organism?
The cell cultures obtained by these techniques were probably all transformed cells
with abnormal chromosome constitutions. The establishment of cell cultures from
a single euploid cell with normal chromosomes proved to be much more difficult.35
Cell Cultures from Plants
Techniques for growing cultures from plant material developed along similar lines
to those derived from animal cells. They also presented similar problems when
cultures were grown from tissues of cells which, even though they were derived from
the same plant, may have had different potentialities. In 1954 a technique was
described for obtaining cultures originating from single cells of crown galls on
marigold (Tagetes erecta), and of tobacco (Nicotiana tabacum) from normal stems.36
The authors referred to these as "plant tissue cultures of single cell origin". This
29 Ibid., p. 229.
30 Ibid.
31 Ibid., p. 245.
32 Katherine S Sanford, Gwendolyn D Likely,
Wilton R Earle, 'The development of variations
in transplantability and morphology within a
clone of mouse fibroblasts transformed to
sarcoma-producing cells in vitro', J. natl. Cancer
Inst. 1954, 15: 215-37, pp. 228-9.
3 Theodore T Puck, Philip I Marcus, 'A rapid
method for viable cell titration and clone
production with HeLa cells in tissue culture: the
use of X-irradiated cells to supply conditioning
factors', Proc. natl. Acad Sci. USA, 1955, 41:
432-7.
3 Theodore T Puck, Philip I Marcus, Steven J
Cieciura, 'Clonal growth of mammalian cells in
vitro', J. exp. Med., 1956, 103: 273-84, p. 274.
35Harris, op. cit., note 27 above, p. 51.
36W H Muir, A C Hildebrandt, A J Riker,
'Plant tissue cultures produced from single
isolated cells', Science, 1954, 119: 877-8.
386
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"Clone"
work was followed by a more extensive investigation, including cultures from
additional plant species, grown from both crown gall and normal tissues. The new
publication contained the following statement:37
Many single cell clones grew well independently, but some either failed to grow (about 10 per
cent) or grew poorly after transfer to agar. The term "clone" is used in accordance with Earl's
[sic] (1955)38 definition. It seems particularly appropriate, since the single cell came from a
heterogeneous mixture and culture propagation is entirely vegetative.
In 1959 Ludwig Bergmann used the term cloning in a publication describing a
different technique for isolating single plant cells for tissue culture.39
During the same period, Frederick Campion Steward and collaborators developed
new techniques for studying the growth of plant cells from tissues that had ceased
cell division. This involved, first, the identification of media containing the correct
composition of growth-regulating substances.40 By exposing small pieces of carrot
tissue to a regulated mixture of growth medium and air, phloem tissue which had
ceased to grow resumed cell division, and eventually even isolated cells would grow
into entire plants, including flowers and seeds.4' The derivatives of phloem explants
derived from a given plant were referred to as a clone.42
In 1970, Steward looked back on the years during which it had become possible
to grow entire plants from isolated somatic cells. He considered that all parts of the
cells were involved in the changes occurring when a quiescent state returned to cell
proliferation.This raised the question whether similar changes could be induced in
the cells of animals. Evidence from the experiments of John Gurdon (see below)
seemed to show that the nuclei of certain animal cells retained all their genetic
information, but that this was released only in contact with the cytoplasm of an
enucleated egg.
Perhaps eventually, the equivalent of the plant techniques here described may induce somatic
cells of animals to embark directly upon an embryological development, and, perhaps, if this
is done, they may even be furnished in some way with the equivalent of a parental blood
supply. Such steps present, however, obviously greater orders of difficulty, even if they do not
constitute insuperable barriers to the free clonal development of higher animals from somatic
cells.43
7 W H Muir, A C Hildebrandt, A J Riker,
'The preparation, isolation, and growth in culture
of single cells from higher plants', Am. J. Bot.,
1958, 45: 589-97.
38 W R Earle, Communication on 'Pure cell
strains', in D C Hetherington (ed.), Annual report
to Tissue Culture Association, 1955, as cited by
Muir et al. on p. 593, note 37. Extensive
enquiries have failed to locate a copy of the
report.
3 Ludwig Bergmann, 'A new technique for
isolating and cloning cells of higher plants',
Nature, 1959, Aug. 22: 648-9.
'4 E M Shantz, F C Steward, M S Smith, R L
Wain, 'Investigations on the growth and
metabolism of plant cells. VI. Growth of potato
tuber tissue in culture: the synergistic action of
coconut milk and some synthetic growthregulating compounds', Ann. Bot., 1955, 19:
49-58.
4 Frederick Campion Steward, 'The control of
growth in plant cells', Sci. Am., Oct., 1963, 209:
104-13.
4 Frederick Campion Steward, Marion 0
Mapes, 'The totipotency of cultured carrot cells:
evidence and interpretations from successive
cycles of growth from phloem cells', J. Indian bot.
Soc., 1963, 42A, Maheshwari Commemoration
vol., 237-46, pp. 238-242.
43Frederick Campion Steward, 'Totipotency,
variation and clonal development of cultured
cells', Endeavour, 1970, 29: 117-24, p. 124.
387
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at https:/www.cambridge.org/core/terms. https://doi.org/10.1017/S0025727300069404
Ursula Mittwoch
Before taking up the topic of development in animals, two interludes dealing with
nomenclature based on immunological science will be inserted.
Interlude 1:
The Clonal Selection Theory of Acquired Immunity
The increasingly widespread use of the word clone and its derivatives for the
offspring of single cells in culture is reflected in the title of F Macfarlane Burnet's
influential Clonal selection theory of acquired immunity, published in 1959, which
dealt with the difficult problem of how cells can make specific antibodies to the vast
variety of different pathogens. It could be argued that the impact of the theory was
enhanced by the choice of title, which implied scientific novelty and at the same
time was easily remembered. Indeed, the author began by saying that in struggling
to find titles for lectures or articles, the first that usually came to mind was "A
biological approach to-, or The natural history of (infectious disease, cancer, war)"
etc." The underlying agent of antibody production was not just a cell, but a clone
of cells. Moreover, the ecological and evolutionary implications of clones, as opposed
to sexually reproducing populations, seemed to represent a simplification of subject
matter. This concept could be applied equally to bacteria.
Burnet's theory was based on the premise that antibody-producing cells formed
part of a mobile population of mesenchymal cells constantly undergoing physiological
and mutational changes. He proposed that, when somatic mutational changes occur,
new clones are initiated.45 Clones that produce antibody globulins corresponding to
particular antigenic determinants will be at a selective advantage, which is expressed
by enhanced proliferation. This will result in antibodies being produced to combat
the large variety of antigens that may be encountered.
Interlude 2:
Monoclonal Antibodies
For practical purposes, antisera raised by injecting foreign proteins into animals
tend to lack sufficient specificity and reproducibility. A way out would be to set up
cultures from individual antibody-secreting cells, which produce only one species of
antibody, but such cultures fail to survive. In 1975, Georges Kohler and Cesar
Milstein overcame this problem by hybridizing lymphocytes, the precursors of
antibody-producing plasma cells, with malignant myeloma cells, which can be
maintained permanently.46 The authors first immunized mice with sheep's red blood
cells and then fused (hybridized) their spleen cells with myeloma cells. The hybrid
cells secreted antibodies against both parents. Individual cells that produced antibodies against the red blood cells were set up in culture, and the clones could
be maintained in culture. In order to become "monoclonal antibodies" in the
4 F Macfarlane Burnet, The clonal selection
theory of acquired immunity, Cambridge
University Press, 1959, pp. 1-2.
45 Ibid., p. 67.
4 Georges Kohler, Cesar Milstein,
'Continuous cultures of fused cells secreting
antibody of predefined specificity', Nature, 1975,
256: 495-7.
388
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"Clone"
immunological sense, however, they needed to undergo additional selection procedures to rid them of determinants derived from the myeloma parent and to express
solely antibodies to a single determinant.47
Because of the immense impact of the technique on clinical medicine and biological
research, Cesar Milstein and Georges Kohler were awarded the Nobel Prize. Hence
the term "monoclonal antibodies" is familiar to many scientists other than those
specializing in immunology.
Experiments with Enucleated Frogs' Eggs
We must now address the question of the developmental potential of a nucleus of
a differentiated animal cell. Is the effect of the nucleus to direct the development of
the phenotype confined along restricted lines, or could even the nuclei of differentiated
cells initiate normal embryonic development? The idea of transplanting somatic
nuclei into eggs has existed since the end of the nineteenth century, but its successful
application had to wait until techniques of activation, enucleation and the transfer
of nucleus into the egg had become available.48 By the 1950s sufficient advances
had been made to enable Robert Briggs and Thomas King to report successful
transplantation in the frog, Rana pipiens.49 By removing the nuclei from frogs' eggs
and replacing them with nuclei from embryos at the blastula stage, the authors
succeeded in raising frogs up to adulthood.
In another series of experiments, King and Briggs made serial transplantations
into enucleated frogs' eggs. This included isolating nuclei from a blastula and
inserting them singly into enucleated eggs, each of which was allowed to develop
into a new blastula. The process was then repeated, using blastulae obtained from
the previous experiments. Since it could be assumed that all blastulae so formed
contained identical nuclei derived from the original blastula, they were referred to
as a "nuclear clone".50 Subsequently, the adjective "nuclear" tended to be omitted,
and all the offspring of a particular blastula were referred to as a clone.
During the 1960s, John Gurdon carried out transplantation experiments on the
South African clawed frog, Xenopus laevis, and in an article in Scientific American,
concluded a description of serial nuclear transplantation as follows: "The effect is
the same as in the vegetative propagation of plants, namely the production of a
clone: a population consisting of many individuals all having an identical set of
genes in their nuclei"; while the legend to an illustration explaining serial transplants
contained the statement: "The cells' genetically identical nuclei are then transplanted
into enucleate eggs, giving rise to a clone: a population comprised of genetically
47Cesar Milstein, 'Monoclonal antibodies, Sci.
Am., Aug. 1980, 243: 66-74.
4' Marie A Di Berardino, Genomic potential of
differentiated cells, New York, Columbia
University Press, 1997, pp. 28-53.
49 R Briggs, T J King, 'Transplantation of
living nuclei from blastula cells into enucleated
frogs' eggs', Proc. natl. Acad Sci. USA, 1952, 38,
455-63.
5 Thomas J King, Robert Briggs, 'Serial
transplantation of embryonic nuclei', Cold Spring
Harbor Symp. quant. Biol., 1956, 21: 271-90,
p. 277.
389
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Ursula Mittwoch
identical individuals".51 The individuals themselves were referred to as "transplant
frogs".
In a later article, Gurdon speculated on the nature of cytoplasmic molecules
that regulate gene activity, but he still maintained that all frogs obtained by the
transplantation of nuclei from the same donor embryo into many recipient eggs
constituted a clone, "because they are all genetically identical twins";52 and again,
the comparison is made with vegetative reproduction as practised in plants. This
comparison was evidently based on the constancy of the nuclear genome rather than
the phenotype resulting from the interaction of any cytoplasmic particles with the
genome.
Mitochondrial DNA
The striking parallelism between the behaviour of chromosomes during meiosis
and the transmission of paired Mendelian characters not only persuaded geneticists
that the chromosomes within the nucleus were the bearers of the hereditary material,
but also gave rise to the supplementary idea that the cytoplasm was devoid of genetic
elements. The opposite view, emerging in the 1950s and 1960s, that some DNA was
present also in a cytoplasmic component, the mitochondria,53 even though supported
by increasingly strong evidence,54 was at first vigorously rejected.5
The relatively massive cytoplasm of frogs' eggs appeared to be particularly rich
in mitochondrial DNA. In two species, Rana pipiens and Xenopus laevis, eggs were
found to contain 300-500 times more DNA than did somatic cells, and the evidence
suggested that most of this DNA was of mitochondrial origin.56 But even these
findings, as well as others, suggesting that mitochondria contained a few dozen
genes,5' did not impinge on the expanding use of the term clone and its exclusive
connection with nuclear genes.
Mitochondria are the power plants of the cell and are now known to contain
genes that are essential for energy generation. In recent years an increasing number
ofmutations have been identified in human mitochondria that give rise to degenerative
diseases, particularly of the brain and of the muscles.58 These mutations are inherited
solely through the mother. Progressively malfunctioning mitochondria have also
been associated with the aging process. Recently it has been established that
51 J B Gurdon, 'Transplanted nuclei and cell
differentiation', Sci. Am., Dec. 1968, 219: 24-35,
pp. 27, 28.
52 Idem, 'Egg cytoplasm and gene control in
development', The Croonian Lecture, 1976, Proc.
R Soc. Lond, B, 1977, 198: 211-47, p. 218.
5 Sylvan Nass, Margit M K Nass,
'Intramitochondrial fibers with DNA
characteristics II. Enzymatic and other hydrolytic
treatments', J.. Cell Biol., 1963, 19: 613-29.
5 D B Roodyn, D Wilkie, The biogenesis of
mitochondria, London, Methuen, 1968, pp. 3-10.
55 D Wilkie, The cytoplasm in heredity,
London, Methuen, 1964, pp. 1-8.
56 Igor B Dawid, 'Evidence for the
mitochondrial origin of frog egg cytoplasmic
DNX, Proc. Nat!. Acad Sci. USA, 1966, 56:
269-76, p. 269.
5 David Wilkie, 'Early recollections of fungal
genetics and the cytoplasmic inheritance
controversy', in M N Hall and P Linder (eds),
The early days of yeast genetics, Plain View, Cold
Spring Harbor Laboratory Press, 1993,
pp. 259-69, p. 263.
58 Douglas C Wallace, 'Mitochondrial DNA in
aging and disease', Sci. Am., Aug. 1997, 277:
40-7.
390
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"Clone"
mitochondrial DNA encodes thirteen polypeptides which interact with a large number
of peptides encoded by the nucleus to form the mitochondrial electron transport
system.59 This suggests that compatibility between the two genetic systems could be
important.
Even mammalian eggs, although very much smaller than those of amphibia,
contain about 100,000 mitochondria, containing 2 x 105 copies of the mitochondrial
genome,60 compared with about a thousand mitochondria in the cells of somatic
cells.6' The large number may be in preparation for the energetic demands of
embryogenesis. An alternative explanation is that, since mitochondria do not replicate
in early embryo development, a large reservoir needs to be present in the oocyte.2
Mitochondria control tissue-specific energy production, and there is interaction
between the mitochondrial and nuclear genomes.6' Even though questions remain
regarding detailed mechanisms-and notwithstanding the fact that the number of
nuclear human genes exceeds that present in mitochondria by a factor of three
magnitudes-there can no longer be any doubt that the question "Do cytoplasmic
genes matter?" must be answered in the affirmative.
More Scientific Definitions
In 1972, Leon Kass published an article opposing different reproductive technologies, and in a section on 'Cloning, or asexual reproduction: state of the art',
went into some detail to define the term clone. The author began by saying that "In
genetic terms, asexual reproduction is distinguished from sexual reproduction ... by
two characteristics: the new individuals are, first, derived from a single parent, and
second, genetically identical to that parent". Furthermore, "An unlimited number
of identical individuals, i.e., a clone, all generated asexually from a single parent,
could be produced by nuclear transplantation".64
The first criterion, that an individual produced by asexual reproduction has only
a single parent would seem to be questionable in the case of individuals produced
by nuclear transplantation into an enucleated egg for two reasons: first, the egg
cytoplasm comes from a second individual, and second, the egg is a sexual cell,
produced by meiosis, rather than a somatic cell, produced by mitosis. The involvement
of the cytoplasm of an egg ensures that the technique has at best some, but not all,
the characteristics of asexual reproduction. The correctness of the second criterion
is questionable because of the presence of mitochondrial genes in the cytoplasm,
which are likely to affect the function of the nuclear genes.
59 Pierre U Blier, France Dufresne, Ronald S
Burton, 'Natural selection and the evolution of
mtDNA-encoded peptides: evidence for
intergenomic co-adaptation', Trends Genet., 2001,
17: 400-6.
'Jim Cummins, 'Mitochondrial DNA in
mammalian reproduction', Rev. Reprod., 1998, 3:
172-82.
61 Guy Brown, The energy of life, London,
HarperCollins, 1999, p. 100.
62 Cummins, op. cit., note 60 above,
pp. 172-3.
63 Ibid., pp. 174-5.
6 Leon R Kass, 'New beginnings in life', in M
P Hamilton (ed.), The new genetics and the future
of man, Grand Rapids, MI, W B Eerdmans,
1972, pp. 15-63, pp. 42-5.
391
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Ursula Mittwoch
Kass rejected the notion of those who would confine the term cloning to largescale replication and use the term "nuclear transfer" for single instances of asexual
reproduction:
... hoping thereby not to bring the opprobrium of the mass use upon individual cases....
While the term clone does imply an aggregate, it is an aggregate which is formed not
horizontally (during one generation) but vertically over time (generation after generation).
Thus even the first asexually-produced offspring and his progenitor together form a clone,
albeit a small one for the time being. "Nuclear transfer" is but the name of one of several
possible techniques that could give rise to a clone and thus does not serve as a generic term
for the genetically and humanly significant features of asexual reproduction. Moreover, the
desire to avoid for the small-scale use the offensive connotation of mass production begs the
question of whether the opprobrium is not equally fitting and leads to the development of
euphemism. I shall thus use "cloning" as synonymous with "asexual production, artificially
induced."65
This paragraph was cited by Robert McKinnell in the preface of his book Cloning:
nuclear transplantation in amphibia, published in 1978, where he explained the reason
for choosing this title: "Biologists generally use the word 'cloning' to refer to the
production of multiple genetically identical individuals. Cloned amphibia, in the
sense of isogenic groups of frogs, are produced by nuclear transplantation, which is
the subject of this book. However, the word 'cloning' is used here in a more general
sense, that is, to refer to one or more individuals produced by the method."' Like
Kass, McKinnell applied the term cloning to the production of a single individual
offspring.
In the same book, the word "clone" is given to a group of frogs that have arisen
by nuclear transplantation from a common blastula and therefore are genetically
identical, or isogenic. "The terms "isogenic groups", "syngenetic series", and "nuclear
transfer clone" are used synonymously in this chapter. Thus "clone" is used here to
mean a group, in lieu of its meaning as a mode of asexual reproduction".67
In the following year, McKinnell published another book, addressed to the general
reader,68 of which a revised edition appeared in 1985.69 By then, there had been
substantial progress in mammalian reproductive technology, including in-vitro fertilization and implantation of embryos into foster mothers. A few mice were claimed
to have been born as a result of nuclear transplantation,70 and the possibility of
using the technology on humans was a subject for speculation, which in turn increased
the use of the words clone and cloning among both scientists and the public. According
to McKinnell's glossary, the meaning of clone had now been extended to comprise
not only the collective, but also the individual: "A group of genetically identical
65 Ibid., p. 43.
6 Robert G McKinnell, Cloning: nuclear
transplantation in amphibia, Minneapolis,
University of Minnesota Press, 1978, pp. vii-viii.
67
Ibid., p. 148.
68 Idem, Cloning: a biologist reports,
Minneapolis, University of Minnesota Press,
1979.
69 Idem, Cloning offrogs, mice, and other
animals, rev. ed. of Cloning: a biologist reports,
Minneapolis, University of Minnesota Press,
1985.
7 K Illmensee, P C Hoppe, 'Nuclear
transplantation in Mus musculus: developmental
potential of nuclei from preimplantation
embryos', Cell, 1981, 23: 9-18.
392
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"Clone"
organisms produced without sexual reproduction; an individual produced asexually".7' The presence of the egg cytoplasm continued to be ignored.
In addition to these two definitions, McKinnell also considered that "[t]he production of more than one embryo from separated cells of a single embryo, without
the intervention of sex, should be regarded as a form of cloning".72 This use of the
term seems to have been foreshadowed by J B S Haldane,73 but the clones that
Haldane envisaged were to be produced by a very different technique.
Gene Cloning
With the advent of recombinant DNA technology, the term clone acquired yet
another meaning for molecular biologists, who extended its use to a segment of
DNA that had been multiplied many times. Stanley Cohen and his co-workers
constructed bacterial plasmids carrying new combinations of DNA segments. These
were inserted into Escherichia coli bacteria, which gave rise to colonies. The authors
wrote: "A single clone that had been selected for resistance to kanamycin and which
was found also to carry resistance to neomycin and sulfonamide, but not to tetracyclin,
chloramphenicol, or streptomycin after transformation of E. coli by EcoRI-generated
DNA fragments of R6-5, was examined further".74
Subsequently it seemed a small step to extend the terminology from the bacterial
clone to the construct of DNA that was contained in it. In Recombinant DNA: a
short course James Watson and his colleagues wrote:
Throughout this book we have frequently used the words "cloned", "cloning," and "clone";
recently they have taken on new and, in some quarters, highly emotive meanings. The word
"clone" was first used to describe a population of cells or organisms all derived from a single
cell or organism by asexual multiplication in such a way that all the individuals in the clone
have the same genetic constitution. When it became possible by recombinant DNA techniques
to take a gene or any other segment of DNA and multiply it in bacteria, the term "gene
cloning" seemed appropriate.75
According to a recent definition in Nature, cloning is "[t]he process of generating
sufficient copies of a particular piece of DNA to allow it to be sequenced or studied
in some other way".76
J B S Haldane and Aldous Huxley
In his essay on science and the future, Haldane considered various possibilities by
which progress in biology could contribute to the betterment of humankind. He
71 McKinnell, op. cit., note 69 above, p. 119.
72Ibid., p. 91.
73 J B S Haldane, 'Biological possibilities for
the human species in the next ten thousand
years', in G Wolstenholme (ed.), Man and his
future, London, J & A Churchill, 1963,
pp. 337-61.
7 Stanley Cohen, Annie C Y Chang, Herbert
W Boyer, Robert B Helling, 'Construction of
biologically functional bacterial plastids in vitro',
Proc. natl. Acad Sci. USA, 1973, 70: 3240-4,
p. 3241.
5 James D Watson, John Tooze and David T
Kurtz, Recombinant DNA: a short course, New
York, Scientific American Books, 1983, p. 206.
76 David Baltimore, 'Our genome unveiled',
Nature, 2001, 409: 814-16.
393
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Ursula Mittwoch
predicted in-vitro fertilization and coined the term ectogenesis for the envisaged
development of the embryo and foetus in the laboratory. The proposed advantages
of these techniques were that they would counteract the fall in the birth rate that
threatened various European countries, and also that they enabled selective breeding
from a small proportion of men and women with superior achievements.77
The ectogenesis theme was elaborated by Aldous Huxley in his futuristic novel
Brave new world,78 though mainly for the production of low-caste individuals, who
were mass-produced in the manner of Ford motor cars. In Huxley's new world,
human reproduction is confined to test-tubes, in which the nutrients are modified
to produce individuals of different classes to fit their future stations in life. Those
destined to be lower class, Gammas, Deltas and Epsilons, who would be needed to
carry out menial tasks, and who are, therefore, required in large numbers, are
subjected to a treatment that induces the fertilized egg to divide several times to
produce from eight to ninety-six identical individuals. Huxley referred to the technique
as "Bokanovsky's Process", and the process of doing so "to bokanovskify".
It should be noted that the method of social engineering described by Huxley
relied more on modifying the environment of the developing individuals than their
genetic make-up. At the same time, the mass production of desired workers was
further promoted by repeated subdivisions of the embryo to be subjected to a specific
treatment, thus maximizing the uniformity of the individuals to be produced.
Thirty years later, Haldane returned to the theme of how to improve the human
race through advances in biology. A new possibility now seemed on the horizon:
We have known how to grow mammalian cells in culture for over 50 years. Human cells, not
only from embryos, children and cancers, but from a sixty-year-old man, have been grown
for years on end. We do not know how to induce them to organize themselves. But we may
find out at any moment, as we have already found out in some cases of plant cells. It is
extremely hopeful that some human cell lines can be grown on a medium of precisely known
chemical composition. Perhaps the first step will be the production of a clone from a single
fertilized egg, as in Brave New World. But this would be of little social value. The production
of a clone from cells of persons of attested ability would be a very different matter, and might
raise the possibilities of human achievement dramatically.79
In this quotation, Haldane uses the term clone twice. The first, in the reference to
Brave new world, relates to the production of multiple individuals from a single
fertilized egg by repeated subdivisions of an embryo, "Bokanovsky's Process". To
refer to the product of the process as a clone would appear to be a novel use of the
term, which, as noted above, was subsequently also adopted by McKinnell.80 Haldane,
however, dismisses this procedure as of little social value. The second reference is to
cell cultures. Many of these would not have originated from single cells, but this
fact may not have seemed important to Haldane, provided each culture was derived
from a single individual. Since all somatic cells of an individual can be assumed to
77 J B S Haldane, Daedalus: or, science and the
future, London, Kegan Paul, Trench, Trubner,
8th impression, 1928, pp. 63-8, 352.
78Aldous Huxley, Brave new world, London,
Chatto & Windus, 1932.
79Haldane, op. cit., note 73 above, p. 352.
80McKinnell, op. cit., note 69 above, p. 91.
394
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"Clone"
have arisen by mitotic divisions from the original fertilized egg, an individual
originating from a cell culture would be a clone within the classical definition of the
term, i.e. a population of individuals that are descended exclusively from somatic
cells, without reference to the number of cells that gave rise to the new individual.8'
Contrary to the statement by Gina Kolata that Haldane, hooked on the mesmerizing studies by Briggs, King, and later Gurdon, speculated on the results of the
frog studies at a scientific symposium,82 there is no mention of the frog studies in the
symposium proceedings,83 including the published discussion on ethical considerations
which follows immediately after Haldane's contribution to the Ciba symposium.'
What Haldane did envisage was the possibility that techniques might become available
to induce human cultured cells to develop into adult individuals, a development that
seemed already feasible in plants. One may surmise that he was referring to the
work of Frederick C Steward, who succeeded in growing entire carrot plants from
somatic cells in culture.85 There can be no doubt that Haldane similarly used the
term "to clone" for the production of human beings from somatic cells grown in
culture, and not for embryos obtained by nuclear transplantation into enucleated
oocytes. He added that: "On the general principle that men will make all possible
mistakes before choosing the right path, we shall no doubt clone the wrong people".86
The juxtaposition of the words clone and cloning with the methods of achieving
human reproduction employed by the totalitarian regime described in Huxley's
novel may have contributed to increasing public anxiety about advances in human
reproductive technologies throughout the following decades. A recent report issued
jointly by two British authorities states that "It is clear that the term cloning carries
an automatic stigma for many because of its association with imagery such as that
portrayed in Brave New World",87 even though the word does not appear in this
book. Indeed, public fear and fascination with the disastrous effects created by the
activities of scientists and their predecessors preceded the publication of this novel
by more than a thousand years.
Goethe and Mary Shelley
The origin of Goethe's ballad of the Sorcerer's apprentice, who converted a broom
into a servant to fetch water from the well, but then could not stop him even though
81 Darlington, op. cit., note 12 above, p. 574.
82
Kolata, Clone: the road to Dolly and
the path ahead, London, Allen Lane, Penguin
Press, 1997, p. 61.
83Wolstenhohne, op. cit., note 73 above.
'4 Discussion, 'Ethical considerations', in
Wolstenholme (ed.), op. cit., note 73 above,
pp. 362-83. However, the original tape recording
reveals that one participant did ask about the
feasibility of allowing a fertilized ovum to
develop to the 8-cell stage, let one cell develop
and deep-freeze the other seven, apparently for
the purpose of transplantation.
85Steward, op. cit., note 41 above.
86 Haldane, op. cit., note 73 above, p. 352.
87 Human Genetics Advisory Commission and
Human Fertilisation and Embryology Authority,
Cloning issues in reproduction, science and
medicine, a report, London, Department of Trade
and Industry, December 1998, p. 19.
395
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Ursula Mittwoch
the incoming water threatened to flood the entire house, has been traced to a tale
by the Greek writer Lucian,88 who lived in the second century AD.
Goethe's sorcerer's apprentice followed in the ancient tradition of magicians, who
carried out their work by uttering secret incantations on inanimate objects like
brooms, or as in the Jewish myth of the Golem, on a piece of clay.89 Mary
Wollstonecraft Shelley created the archetypal mad scientist in her novel, Frankenstein,
first published in 1818. The book is named after its principle character, a Swiss
student of anatomy and chemistry, who thought that he had discovered the secret
of life and was thus able to bestow animation on lifeless matter.90 He thereupon set
out to create a man from materials obtained from the dissecting room and the
slaughter house. Alas, the result of his efforts turned out to be a demon, who pursued
his creator and finally killed him. The story was further popularized by a successful
Hollywood film in 1931,91 since when the name Frankenstein has become a household
word, albeit one that is often transferred from the mad scientist to the monster that
he created.
Public Interest: A Glance at the Media
The experiments in nuclear transfer in frogs were originally undertaken to elucidate
the problem of cell and tissue differentiation by providing information on whether
the nucleus of an already differentiated cell could substitute for the original nucleus
derived by the fusion of egg and sperm. At first, interest in this work was confined
to specialists in the field, but before long it entered the domain of a wider public.
Already in 1968, one British newspaper proclaimed that "one of the of the most
extraordinary of the possibilities now being explored has already been reported
under such headlines as 'Einstein from Cuttings' and 'J'aime Mozart XXXIII'. More
scientifically it is referred to as 'cloning people'-the creation of genetically identical
individuals from body cells".92
The emergence of a variety of reproductive technologies was undoubtedly a reason
for further increasing public interest, while anxiety about their ethical implications
gave rise to yet more publicity. Artificial insemination, which had long been used in
animal husbandry, came to be applied as a means of assisted reproduction in humans,
while the much more complex technique of in-vitro fertilization was debated long
before the first "test-tube" baby was born in 1978. 9 In his critical review of
88 Ludwig Geiger (ed.), Goethe's Werke, 4th
ed., 10 vols, Berlin, G Grote, 1890, vol.1,
pp. 146-50. "The attribution of the poem to
Lucian is based on Struwe, Zwei Balladen von
Goethe, verglichen mit griechischen Quellen,
woraus sie geschopft sind, Konigsberg, 1826".
'9Joseph Dan, 'Golem', in R J Z Werblowsky,
G Wigoder (eds), The Oxford Dictionary of the
Jewish Religion, New York, Oxford University
Press, 1997, p. 280.
9 Mary Wollstonecraft Shelley, Frankenstein,
or, the modern Prometheus, 3 vols, London,
Lackington, Hughes, Harding, etc., 1818.
91 Jon Turney, Frankensteinsfootsteps: science,
genetics and popular culture, New Haven and
London, Yale University Press, 1998,
pp. 29-34.
92 Gordon Rattray Taylor, 'Carbon copy
people', Observer, 10 March 1968, Colour Suppl.,
pp. 6-12, p. 9.
93R G Edwards, Ruth E Fowler, 'Human
embryos in the laboratory', Sci. Am., Dec. 1970,
223: 44-54.
396
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"Clone"
reproductive technologies, including in-vitro fertilization and cloning, Leon Kass
regarded artificial insemination as the beginning of a slippery slope that would finish
with ectogenesis, "the full laboratory growth of a baby from sperm to term"."94
A year earlier, a well-publicized article by James Watson had appeared entitled
'Moving toward the clonal man. Is this what we want?'. Watson explained that the
rapid progress in working out the conditions for test-tube conceptions would before
long enable experiments, similar to those that produced clonal frogs, to be carried
out with human cells.
The growing up to adulthood of these first clonal humans could be a very startling event, a
fact already appreciated by many magazine editors, one of whom commissioned a cover with
multiple copies of Ringo Starr, another of whom gave us overblown multiple likenesses of
the current sex goddess, Raquel Welch.95
Watson's article attracted a reply, casting doubt on the premise that the technique
of transplanting a nucleus of a human cell into an enucleated egg would result in a
fairly exact copy of the nuclear donor, since "there is plenty of evidence in other
creatures that the host egg's cytoplasm would substantially affect the outcome".96
However, the possible effect of the cytoplasm on the developing embryos has not,
so far, been a matter of public interest.
In the late 1970s, a book appeared that electrified the media and caught scientists
unprepared. Its title was In his image: the cloning of a man, and it described the
story, which eventually ended successfully, of how the author, David Rorvik, became
the chosen intermediary to pave the way for a wealthy man who wished to secure
an heir by the new process of "cloning".97 The official provenance of the book was
"Genetic engineering". Could the story be true, or was it a hoax? Notwithstanding
a ten-page bibliography that would have done credit to a textbook, In his image
became a best-seller. In the end, following a lawsuit, the publishers (but not the
author) admitted that the story was untrue.98
Those who thought in 1978 that cloning a human being was "impossible", were
likely to change their opinion within the next twenty years. The birth of Dolly the
sheep was announced in 1997, albeit without mention of the words "clone" or
"cloning"; but these terms were disseminated by the media even before publication
day, when the issue of Nature proclaimed "A flock of clones" on its front cover.9
Following the birth of Dolly and its handling by the media, cloning issues
have generated wide public interest, where promises of unprecedented benefits are
counteracted in the public mind by a long tradition of fear that tampering with the
natural order of things will lead to disastrous consequences. There is little doubt
that simplified terminology has helped people to become familiar with an advance
op. cit. note 64 above, pp. 42-3.
95James D Watson, 'Moving toward the
clonal man. Is this what we want?', Atlantic
Monthly, May 1971: 50-3, p. 51.
9 Lionel Jaffe, 'Not-so-obsolescent mothers',
Atlantic Monthly, July 1971: 25-6.
97 David M Rorvik, In his image: the cloning
of a man, London, Hamish Hamilton, 1978.
94 Kass,
98 Kolata, op. cit., note 82 above, pp. 101-2.
9 I Wilmut, A E Schnieke, J McWhir, A J
Kind, K H S Campbell, 'Viable offspring derived
from fetal and adult mammalian cells', Nature,
1997, 385: 810-13.
397
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Ursula Mittwoch
in science. Whether it has helped the public understanding of science, or indeed,
science itself, is another question.
What's in a Name?
In order to keep track of the progressive changes in meaning of the scientific term
clone, let us consider the summary provided in Table 1. The different usages fall into
four categories: (1) the original, or classical, meaning of the term, i.e. the collective
of individuals descended by asexual reproduction from a single organism; (2) cell
cultures derived from a single cell; (3) animals produced by the replacement of the
nucleus of an oocyte by a diploid nucleus of a somatic cell; (4) the multiplication of
genes and other DNA sequences.
As shown in the second section of the Table, the use of the term clone was first
extended from garden plants to unicellular protozoa descended by mitosis from a
common ancestor. Then, by equating asexually produced protozoa with the pure
lines obtained from self-fertilizing flowering plants, Jennings obscured the boundary
between vegetative and sexual reproduction, the latter involving germ cells produced
by meiosis. The application ofthe term clone by Sanford and colleagues to mammalian
cell cultures originating from a single tissue cell-a technique first successfully
performed in 1948-further extended its use to individual cells of multicellular
organisms, which would naturally divide by mitosis, whereas the definition by Puck
and his fellow workers could also apply to offspring produced by self-fertilization.
The clones of complete carrot plants produced by Steward and Mapes in the late
1950s are closest to the classical definition, apart from the fact that the carrots were
produced from single somatic cells rather than macroscopic pieces of plants.
Also during the 1950s, the term clone began to be used for the offspring produced
by replacing the nuclei of oocytes with nuclei of somatic cells (Table 1, section 3).
While the cell culture terminology could be viewed as an extension of the classical
usage, the nuclear replacement technique added a new dimension, since it was applied
to offspring originating from an egg, albeit an enucleated one. Other changes
followed. While the use of many nuclei from the same embryo for nuclear replacement
led to the definition of a clone as a population of genetically identical individuals,
this in turn gave rise to the idea of identical twins being clones, and that, moreover,
all clones originate in asexual, or even vegetative, reproduction. Eventually the term
was extended from the collective to the individuals composing it.
As indicated in the last section of the Table, with the rise of molecular genetics,
its practitioners adopted the term cloning for their own technique of multiplying
sequences of DNA. Today, this usage is widely employed by molecular geneticists,
but it is the nuclear replacement technique that has given rise to Dolly that has
caught the interest of the public.
Ambiguous Nomenclature
Defining a clone as a population of genetically identical individuals is no longer
accurate, since an investigation of the mitochondrial DNA (mtDNA) of Dolly and
398
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"Clone"
Table 1:
Changes in the usage of the term clone, resulting in four categories of meaning
Year
Definition
Author
1903
The collection of plants propagated vegetatively from a common
ancestor.
Collective name of all the plants asexually reproduced by
division, grafting, etc., from one (seedling) ancestor.
A group of organisms descended by mitosis from a common
ancestor.
Webber
1934
1937
1929
1948
1956
1958
1959
1963
1956
1968
1972
1975
1985
1983
All individual protozoa descended by uniparental reproduction
(i.e. binary fission) from a single individual. In addition, the
concept of clone was equated with that of a pure line, i.e. the
descendants of a single self-fertilizing individual.
Mammalian cell cultures originating from a single isolated tissue
cell.
"A clone is a population of cells whose members are descendent
from the same single organism".
Cultures originating from single cells of flowering plants.
The word cloning used for the technique of growing cultures
from isolated plant cells.
Complete carrot plants derived from a particular strain by
culturing individual somatic cells.
Serial transplantation of isolated nuclei from frog blastulae into
enucleated oocytes give rise to nuclear clones.
A population of genetically identical individuals.
Cloning is synonymous with asexual reproduction artificially
induced. A single parent and offspring so produced form a clone.
All frogs obtained by transplantation from the same embryo are
identical twins. Their origin is akin to vegetative reproduction.
A group of genetically identical organisms; an individual
produced asexually.
Crane and Lawrence"
Darlington"'
Jennings"
Sanford, et al.v
Puck, et al.
Muir, et alvl
Bergmannv..
Steward and Mapes"
King and Briggsx
A gene or other piece of DNA multiplied in bacteria.
Gurdonx
Kassx"
Gurdonxl
McKinnellx"v
Watson"
'Herbert J Webber, 'New horticultural and agricultural terms', Science, 1903, 18: 501-3.
'M B Crane and W J C Lawrence, The genetics of garden plants, London, Macmillan, 1934, p. 213.
iC D Darlington, Recent advances in cytology, 2nd ed., London, Churchill, 1937, p. 574.
"vH S Jennings, 'Genetics of the protozoa', BibL Genet., 1929, 5: 105-330, p.232.
vKatherine K Sanford, Wilton R Earle and Gwendolyn D Likely, 'The growth in vitro of single isolated tissue cells',
J. natl. Cancer Inst., 1948, 9: 229-46.
ViTheodore T Puck, Philip I Marcus, Steven J Cieciura, 'Clonal growth of mammalian cells in vitro', J. exp. Med.,
1956, 103: 273-84, p. 274.
"W H Muir, A C Hildebrandt, A J Riker, 'The preparation, isolation, and growth in culture of single cells from
higher plants', Am. J. Bot., 1958, 45: 589-97, p. 593.
ViiiLudwig Bergmann, 'A new technique for isolating and cloning cells of higher plants, Nature, 1959, Aug. 22: 648-9.
"'Frederick Campion Steward, Marion 0 Mapes, 'The totipotency of cultured carrot cells: evidence and interpretations
from successive cycles of growth from phloem cells', J. Indian bot. Soc., 1963, 42A, Maheshwari Commemoration vol.,
237-46, pp. 238-42.
xThomas J King, Robert Briggs, 'Serial transplantation of embryonic nuclei', Cold Spring Harbor Symp. quant. Biol.,
1956, 21: 271-90, p. 277.
XiJ B Gurdon, 'Transplanted nuclei and cell differentiation', Sci Am., Dec. 1968, 219: 24-35, pp. 27, 28.
""Leon R Kass, 'New beginnings in life', in M P Hamilton (ed.), The new genetics and the future of man, Grand
Rapids, MI, W B Eerdmans, 1972, pp. 15-63, 42-5.
XiiiJ B Gurdon, 'Egg cytoplasm and gene control in development', The Croonian Lecture, 1976, Proc. PR Soc. Lond.,
B, 1977, 198: 211-47, p. 218.
XivRobert G McKinnell, Cloning offrogs, mice, and other animals, rev. ed. of Cloning: a biologist reports, Minneapolis,
University of Minnesota Press, 1985, p. 119.
x"James D Watson, John Tooze and David T Kurtz, Recombinant DNA: a short course, New York, Scientific American
Books, 1983, p. 206.
399
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Ursula Mittwoch
nine other sheep produced by somatic nuclear transfer showed that the mtDNA was
derived from the cytoplasm of the enucleated oocytes, thus making the sheep "genetic
chimeras".'°° Furthermore, the statement by Gurdon and Colman'0' that the mtDNA
of mammalian clones is entirely maternal in origin is surely significant. If a clone
originates from a nuclear donor plus an egg cytoplasm of maternal, i.e. "mother"
origin, the idea that it is derived from a single parent has evidently been abandoned,
while its origin in asexual reproduction is questionable.
Ambiguous nomenclature with regard to eggs developing into embryos by unorthodox pathways is not confined to cloning. Half a century ago, Alan Boyden
questioned the appropriateness of referring to parthenogenesis as asexual reproduction and emphasized that "there is no such thing as an asexual egg".'02 The
history of an egg's development is at least as important as its subsequent fate, and
a modification of sexual reproduction is not to be confused with asexual reproduction.
Similarly, and apparently independently, I myself pointed out in 1978 that, since
parthenogenesis involves the production of an egg, which plays an essential role in
the development of the embryo, the process should be regarded as incomplete sexual
reproduction.'03 On the other hand, the reason given by Roger Hughes for regarding
parthenogenesis as not "strictly clonal" is that the process can proceed by different
routes that do not necessarily preserve the maternal genotype.'04
Whereas parthenogenesis remained an issue that has been largely confined to
scientists, the topic of clones and cloning has become of increasing concern to the
public. While scientists in different specialties still attach different meanings to the
terms, the public and popular scientific journals identify them with the technique
that has given rise to Dolly.l05
In order to clarify the terminology of cloning as potentially applicable to humans,
it has been subdivided into two apparently distinct meanings: "reproductive cloning",
defined as "where an entire animal is produced from a single cell by asexual
reproduction", and "therapeutic cloning", involving nuclear replacement technology
not leading to the creation of identical individuals.'06 This evades the question
whether the process of embryo splitting that leads to the formation of identical twins
is included in the first category, even though this technique has been described as
cloning.'07 It has also recently been pointed out that the identification of "nuclear
replacement" with cloning leads to confusion, since replacement by two haploid cells
Matthew J Evans, Cagan Gurer, John D
Loike, Ian Wilmut, Angelika E Schnieke, Eric A
Schon, 'Mitochondrial DNA genotypes in nuclear
transfer-derived cloned sheep', Nat. Genet., 1999,
23: 90-3.
101 J B Gurdon, Alan Colman, 'The future of
cloning', Nature, 1999, 402: 743-6, p. 743.
102 Alan Boyden, 'Is parthenogenesis sexual or
asexual reproduction?', Nature, 1950, 166: 820.
103 Ursula Mittwoch, 'Parthenogenesis', J. med
Genet. 1978, 15: 165-81, pp. 165-6.
1 Roger N Hughes, A functional biology of
clonal animals, London, New York, Chapman
and Hall, 1989, p. 8.
105 Andrea Graves, 'Clone farm', New Sci., 18
Aug. 2001: 4-5.
1 Human Genetics Advisory Commission and
Human Fertilisation & Embryology Authority,
Cloning issues in reproduction, science and
medicine. A consultation document, n.p., 1998,
pp. 7-8.
'07Vasilios Tanos, Joseph G Shenker,
'Reproductive health care policies around the
world. Is human cloning justified?', J. assist.
Reprod Genet., 1998, 15: 1-9.
400
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"Clone"
could lead to biparental inheritance.'08 A more accurate term to describe the Dolly
technique would be: somatic nuclear replacement of an oocyte nucleus.
The multitude of meanings that have accumulated over the years is in stark
contrast to the expressed purpose of the originator of the term clon, which was to
describe an assemblage of cultivated plants propagated vegetatively rather than by
seed, and which should not suggest any other meaning.'" Why did this purpose fail?
Could it be that the additional desiderata put forward by Webber, that the word
should be short, euphonious, phonetically spelled and easily pronounced, unfitted it
as a scientific term, whose characteristics have been described as constancy of
meaning, ugliness and emotional neutrality?"0 True, the large majority of scientific
terms, dating from Chaucer to the twentieth century, are polysyllabic"' and often
not easy to memorize. On the other hand, the word gold, which is phonetically not
dissimilar to clone, has existed for more than a thousand years and still refers to the
same chemical element. We must conclude that the multiple meanings of clone are
not due to popular usage, but to the desire of scientists, unhampered by any
regulatory body, to extend the term to a variety of newly discovered phenomena
with only partially overlapping characteristics. In the process, the original meaning
of clone has been almost forgotten, even though it should still play an important
role in the science of fruit growing. For instance, edible bananas are always seedless,
and several hundred clones are thought to exist, ofwhich more that half are triploid."2
It is to be hoped that the term will not be abandoned in its appropriate setting
because it has been pre-empted for different purposes in the biomedical sciences.
The history of the term clone illustrates the danger of placing concepts with only
partially overlapping characteristics under one umbrella designation, particularly in
communications between scientists and the general public. In a recent essay about
the genome, Horace Freeland Judson commented on the confusion engendered by
the use of the term "gene" in place of "allele", and wrote that "Public misinformation
is largely and in origin the fault of scientists themselves"."3 Sloppy nomenclature
provides a fertile soil for the media and writers of science fiction to play on people's
ancient mistrust of scientists. It is hardly surprising that the word clone-whose
meaning has run the gamut from plants that are merely transplanted parts of the
same individual, to sheep and humans with very different origins-provided such
an opportunity. Evidently, far more vigilance is needed on the part of referees and
editors to ensure accurate usage of scientific terms.
"'Jacek Z Kubiak, Martin H Johnson,
'Human infertility, reproductive cloning and
nuclear transfer: a confusion of meanings',
Bioessays, 2001, 23: 359-64.
"'9Webber, op. cit., note 8 above.
"°T H Savory, The language of science, 2nd
ed., London, Andre Deutsch, 1967, p. 112.
..' Ibid., pp. 47-63, 88-111.
12 J W Purseglove, Tropical crops:
monocotyledons 2, Harlow, Longman, 1972,
pp. 351-5.
"' Horace Freeland Judson, 'Talking about
the genome', Nature, 2001, 409: 769.
401
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Ursula Mittwoch
When terminology shifts, specialists, like so many Humpty Dumpties, will be able
to discern the intended meaning correctly, but the general public, just like Alice, will
be confused when confronted by ambiguous information."4 Popular confusion is
likely to perpetuate the long tradition of mistrusting grand claims made by scientists.
"' Even readers of Nature (2001, 412: 848)
may be puzzled by a recent 'News in brief' piece
headed 'No charge for Japan's cloned mice',
which begins: "The mouse clones that formed the
backbone of the international effort to make
sense of the mouse genome ... are to be made
available to researchers free of charge." When it
is further stated that 21,000 clones have been
given away, it becomes clear that the information
is not about mice but pieces of DNA.
402
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